Collective synchronization of undulatory movement through contact

TL;DR

This study shows that physical contact between undulatory robots can lead to synchronization of their movements, revealing new collective behaviors and potential benefits in energy efficiency and safety.

Contribution

It introduces a phase-oscillator model for contact-induced synchronization in undulatory robots and demonstrates its validity through experiments and simulations.

Findings

Robots synchronize in-phase and anti-phase through collisions.

Synchronization reduces interaction forces, improving safety and energy efficiency.

Contact interactions can produce novel collective motion in active matter.

Abstract

Many biological systems synchronize their movement through physical interactions. By far the most well studied examples concern physical interactions through a fluid: beating cilia, swimming sperm and worms, and flapping wings, all display synchronization behavior through fluid mechanical interactions. However, as the density of a collective increases individuals may also interact with each other through physical contact. In the field of "active matter" systems, it is well known that inelastic contact between individuals can produce long-range correlations in position, orientation, and velocity. In this work we demonstrate that contact interactions between undulating robots yield novel phase dynamics such as synchronized motions. We consider undulatory systems in which rhythmic motion emerges from time-independent oscillators that sense and respond to undulatory bending angle and speed. In pair experiments we demonstrate that robot joints will synchronize to in-phase and anti-phase oscillations through collisions and a phase-oscillator model describes the stability of these modes. To understand how contact interactions influence the phase dynamics of larger groups we perform simulations and experiments of simple three-link undulatory robots that interact only through contact. Collectives synchronize their movements through contact as predicted by the theory and when the robots can adjust their position in response to contact we no longer observe anti-phase synchronization. Lastly we demonstrate that synchronization dramatically reduces the interaction forces within confined groups of undulatory robots indicating significant energetic and safety benefits from group synchronization. The theory and experiments in this study illustrate how contact interactions in undulatory active matter can lead to novel collective motion and synchronization.